Small
extracellular vesicles (sEVs) generated from the endolysosomal
system, often referred to as exosomes, have attracted interest as
a suitable biomarker for cancer diagnostics, as they carry valuable
biological information and reflect their cells of origin. Herein,
we propose a simple and inexpensive electrical method for label-free
detection and profiling of sEVs in the size range of exosomes. The
detection method is based on the electrokinetic principle, where the
change in the streaming current is monitored as the surface markers
of the sEVs interact with the affinity reagents immobilized on the
inner surface of a silica microcapillary. As a proof-of-concept, we
detected sEVs derived from the non-small-cell lung cancer (NSCLC)
cell line H1975 for a set of representative surface markers, such
as epidermal growth factor receptor (EGFR), CD9, and CD63. The detection
sensitivity was estimated to be ∼175000 sEVs, which represents
a sensor surface coverage of only 0.04%. We further validated the
ability of the sensor to measure the expression level of a membrane
protein by using sEVs displaying artificially altered expressions
of EGFR and CD63, which were derived from NSCLC and human embryonic
kidney (HEK) 293T cells, respectively. The analysis revealed that
the changes in EGFR and CD63 expressions in sEVs can be detected with
a sensitivity in the order of 10% and 3%, respectively, of their parental
cell expressions. The method can be easily parallelized and combined
with existing microfluidic-based EV isolation technologies, allowing
for rapid detection and monitoring of sEVs for cancer diagnosis.
We present an approach
to improve the detection sensitivity of
a streaming current-based biosensor for membrane protein profiling
of small extracellular vesicles (sEVs). The experimental approach,
supported by theoretical investigation, exploits electrostatic charge
contrast between the sensor surface and target analytes to enhance
the detection sensitivity. We first demonstrate the feasibility of
the approach using different chemical functionalization schemes to
modulate the zeta potential of the sensor surface in a range −16.0
to −32.8 mV. Thereafter, we examine the sensitivity of the
sensor surface across this range of zeta potential to determine the
optimal functionalization scheme. The limit of detection (LOD) varied
by 2 orders of magnitude across this range, reaching a value of 4.9
× 10
6
particles/mL for the best performing surface
for CD9. We then used the optimized surface to profile CD9, EGFR,
and PD-L1 surface proteins of sEVs derived from non-small cell lung
cancer (NSCLC) cell-line H1975, before and after treatment with EGFR
tyrosine kinase inhibitors, as well as sEVs derived from pleural effusion
fluid of NSCLC adenocarcinoma patients. Our results show the feasibility
to monitor CD9, EGFR, and PD-L1 expression on the sEV surface, illustrating
a good prospect of the method for clinical application.
Being a key player in intercellular communications, nanoscale extracellular vesicles (EVs) offer unique opportunities for both diagnostics and therapeutics. However, their cellular origin and functional identity remain elusive due to the high heterogeneity in their molecular and physical features. Here, for the first time, multiple EV parameters involving membrane protein composition, size and mechanical properties on single small EVs (sEVs) are simultaneously studied by combined fluorescence and atomic force microscopy. Furthermore, their correlation and heterogeneity in different cellular sources are investigated. The study, performed on sEVs derived from human embryonic kidney 293, cord blood mesenchymal stromal and human acute monocytic leukemia cell lines, identifies both common and cell line‐specific sEV subpopulations bearing distinct distributions of the common tetraspanins (CD9, CD63, and CD81) and biophysical properties. Although the tetraspanin abundances of individual sEVs are independent of their sizes, the expression levels of CD9 and CD63 are strongly correlated. A sEV population co‐expressing all the three tetraspanins in relatively high abundance, however, having average diameters of <100 nm and relatively low Young moduli, is also found in all cell lines. Such a multiparametric approach is expected to provide new insights regarding EV biology and functions, potentially deciphering unsolved questions in this field.
Electrokinetic principles such as streaming current and streaming potential are extensively used for surface characterization. Recently, they have also been used in biosensors, resulting in enhanced sensitivity and simpler device architecture. Theoretical models regarding streaming current/potential studies of particle-covered surfaces have identified features such as the particle size, shape and surface charge to influence the electrokinetic signals and consequently, the sensitivity and effective operational regime of the biosensor. By using a set of well-characterized proteins with varying size and net surface charge, this article experimentally verifies the theoretical predictions about their influence on the sensor signal. Increasing protein size was shown to enhance the signal when their net surface charge was either opposite to that of the sensor surface, or close to zero, in agreement with the theoretical predictions. However, the effect gradually saturates as the protein size exceeds the coulomb screening length of the electrolyte. In contrast, the proteins containing the same type of charge as the surface show little or no difference, except that the signal inverts. The magnitude of the surface charge was also shown to influence the signal. The sensitivity of the technique for protein detection varied over two orders of magnitude, depending upon the size and surface charge. Furthermore, the capacity of the electrokinetic method for direct electrical detection of various proteins, including those carrying little or no net electric charges, is demonstrated.
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